DE20101028U1 - Flashlight, especially table lamp or presentation plate - Google Patents

Description

Description
Lamp, especially table lamp or presentation plate

The invention relates to a lamp, in particular a table lamp or a presentation plate, with a lamp body accommodating the light source or light sources.

Lamps of the type mentioned above are no longer used exclusively as light-emitting lighting objects, but also for individual home or business interior design. The lamp serves as a visually appealing eye-catcher, in which
the purpose of lighting may take a back seat.

Recently, plastic figure-like bodies have become popular, with a light source inside that illuminates the partially transparent, brightly colored lamp body. Such figures serve as illuminated decorations both inside and outside.

Also known are bundles of thin-diameter glass fiber strands that are illuminated from below and that emit the majority of the incident light, particularly through their front sides. Such lamps are also primarily used for
decorative purposes.

But also in the business sector, directly or indirectly effective lighting is used, especially for advertising purposes
which serve to promote a product.

The object of the present invention is to create a new lamp with expanded possibilities.

This object is achieved by the lamp according to claim 1, which is characterized according to the invention in that the lamp body

per has an upper, horizontally arranged flat surface from which the rays originating from at least one light source emerge vertically. Transparent objects such as glass bottles, glasses or other at least partially transparent objects can be placed on the flat horizontal surface of this lamp body, the base of which is then illuminated. Depending on the structure and color of the object placed on the lamp, special light refractions and reflections occur, which allow the most diverse lighting images to be presented in the room. In particular, such a lamp can also be used as a presentation plate for at least partially transparent goods placed there, which attract the attention of the viewer due to the light refraction.

In principle, such a lamp can be of any shape, as long as it forms an upper surface that can be illuminated from below by the existing light sources. Preferably, however, the lamp body itself is disc-shaped, i.e. flat.

Light bulbs often have the disadvantage of generating a lot of heat, which can lead to the lamp body being exposed to temperature-related damage. In the case of glass bodies, this can lead to cracks and bursting, and in the case of plastic bodies, to the melting of the material in question. Light-emitting diodes are therefore preferably used as the light source or light sources. Special requirements can be taken into account when choosing the light-emitting diodes, i.e. monochrome diodes, e.g. blue, green, orange or yellow, can be used, whose colored light shows the desired room atmosphere even without a body being turned off. If a number of diodes are selected as the light source, attractive mixed colors can also be created using the selected light colors. If necessary, such diodes that

emit different colors depending on the voltage, and also produce controllable effects, which is also possible in a corresponding way by controlling the diodes individually in the case of several diodes emitting different colors and creating mixed colors that change over time. This does not exclude the possibility of other color variants or shadow images being emitted towards the ceiling via filters, grids or similar.

Preferably, the or at least one of the light-emitting diodes is plugged into a socket in an exchangeable manner. This measure provides easy-to-use options for redesigning the lamp. The diodes available on the market today are relatively inexpensive, so that there are advantages not only in the rarely required installation of a replacement diode due to the long service life of the diodes, but above all in the production of a different color spectrum or a lower luminosity.

Preferably, the diode or at least one of the diodes is arranged in a hollow reflector. Such a hollow reflector increases the light output of this light-emitting diode. The shape of the light-emitting diode glass body limits the main beam direction of the light-emitting diode to a relatively small cone angle, but the amount of radiation emitted laterally and lost without the use of a reflector is not insignificant. The light-emitting diode is centered by the reflector through the opening in the hollow reflector, namely a through hole in its rear part through which the light-emitting diode can be pushed, i.e. it is always straightened up with slightly bent wire-shaped power connections so that it is aligned exactly longitudinally. In addition, the diodes are protected against impacts by their frictional arrangement in the opening in the hollow reflector.

stress and also breaking of the current contacts. The hollow reflector or, in the case of several diodes surrounded by hollow reflectors, each of the hollow reflectors has a conically widening, preferably conical reflector inner jacket at the level of the light-emitting chip of the light-emitting diode. This jacket part reflects the light components emitted radially by the light-emitting diode in the direction of the remaining emitted radiation. The conical or at least essentially conical reflector part preferably forms an angle of 20° to 45° with the common hollow reflector and lamp housing longitudinal axis, whereby the hollow reflector can optionally have a cylindrical jacket part between two conical jacket parts, which has the advantage that the reflector diameter is smaller than would be the case with a continuously conical reflector jacket. In the first casing part, the light emitted sideways, i.e. radially, from the light point (diode chip) is reflected forwards, i.e. towards the opening of the lamp head. Any further scattered light in a radial direction that is emitted sideways from the tip of the LED glass body is reflected in a corresponding manner by the second conical casing part. The hollow reflector can be designed so that it only slightly protrudes over the front end of the diode glass and/or so that the LED is arranged at least 0.5 cm behind the open end of the lamp head. The latter variant is particularly recommended if the diode is to be protected against external impacts or shocks or other mechanical damage. The lamp, or the table lamp or the presentation stand, is powered by a transformer that is fed from a conventional socket (220 V or 110 V). If necessary, the transformer voltage output can be regulated within a small range in which the diodes can be operated without overload.

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Depending on the desired luminosity, the lamp can also contain several light-emitting diodes, each of which is preferably surrounded by a hollow reflector, with the hollow reflectors possibly forming a honeycomb-shaped, one-piece body. Ultimately, this is an arrangement of several adjacent hollow reflectors, each with integrated diodes, with the diodes being able to be arranged on a circular, elliptical, rectangular or otherwise shaped surface, as well as on lines, L-shapes or other desired patterns. If required, it can also be provided that individual diodes or groups of diodes are controlled separately or regulated in the power supply via a control circuit.

All of these designs make use of the advantage offered by diodes, which means that only about 13% of the energy is required compared to conventional light bulbs, while maintaining essentially the same level of brightness. Furthermore, the heat radiation from diodes is many times lower than that of a light bulb.

In order to overcome the disadvantage of most diodes, which can only emit (almost) monochromatic light, it is also possible within the scope of the present invention to embed the light-emitting LED chip in a plastic mass with fluorescent or phosphorescent particles. Fluorescence and phosphorescence are physically summarized as so-called luminescence phenomena; the main difference is only the duration of the light. Luminescence effects can be used to ensure that the light emitted by the LED chip (e.g. in blue color corresponding to approx. 480 nm) excites particles capable of luminescence. The absorbed radiation is then emitted again in full or in part in a more or less short time, although the emitted light can only have a wavelength as short as that absorbed. This

leads to a spectral shift in the light emitted by the luminescent particles (compared to the primary radiation from the light-emitting diode). The primary radiation and the luminescent radiation lead to a spectral curve resulting from the additive light intensities, which is visible as a mixed color. The disadvantage of previous attempts to attach the luminescent particles near the LED chip is that the slight increase in temperature of the light-emitting diode leads to changed radiation characteristics, in other words, the color emitted by such an LED is not temperature-stable.

In order to remedy this, according to a further development of the present invention, it is proposed to coat the light-emitting diode glass body with a layer that has luminescent particles embedded in plastic (preferably acrylic) as a fluorescent or phosphorescent material. Unlike conventional attempts to apply the luminescent particles close to the chip, coating the glass body does not lead to any significant temperature impairments due to the greater distance to the LED chip. The coating in question can be applied by spiking or by means of a dipping process, the latter in which the diode is briefly dipped into a heated liquid solution of the liquid plastic doped with dissolved luminescent particles. Depending on the desired application thickness, the dipping process can be repeated several times. Xe light-emitting diodes, which emit a relatively bright but cold white-blue light, are preferably used for such coatings. In order to make the perceived radiation "warmer", a xenon diode, for example, can be provided with a coating that appears orange, which causes a color shift via the luminescence effects described.

According to a further embodiment of the invention, the lamp body can consist at least partially of light-transparent plastic.

Embodiments of the invention are illustrated in the drawings. They show

Fig. 1 to 3

three different views of a presentation plate according to the invention,

Fig. 4 and 5

each sectional view of the presentation plate with different numbers of LEDs,

Fig.6

an enlarged sectional view through a LED/reflector unit,

Figs. 7 and 8

Schematic representations of possible applications of the presentation plate.

The presentation plate 10 shown in Figs. 1 to 5 consists essentially of a lamp body 11, which is essentially flat and cylindrical, i.e. has approximately the shape of a disk. The lamp body has an on/off switch 12 on its cylindrical casing, via which the respective LEDs 13 can be switched on. Each of the LEDs is detachably plugged into a circuit board 14 with appropriately prepared power connections. The LEDs are surrounded by a reflector 15 with an inner casing mirror coating. The presentation plate is closed on the underside by a base plate 16. The presentation plate has an upper flat surface 17 from which the light radiation coming from the diodes 13 emerges vertically upwards. As indicated in Figs. 7 and 8, light-permeable bodies, such as a bottle, can be placed in the area of the light exit openings.

see 18 or a glass 19 or any other object that is illuminated from below when the LEDs are switched on. Depending on the shape of these objects, the selected "light color" of the diodes and the lighting intensity, optical impressions are created that draw the viewer's attention to the illuminated object. The presentation plate 10 is therefore ideally suited as a means of lighting for the advertising industry.

As can be seen from the embodiment according to Fig. 1 to 3, an approximately circular light exit surface can be created by seven diodes. Alternatively, however, it is possible to use, for example, only one light-emitting diode 13, as shown in Fig. 4. The illustration according to Fig. 5 shows a diagonal cross-sectional view of a further embodiment in which five light-emitting diodes are arranged along the diagonal. Next to this diagonal there are two rows on either side with four light-emitting diodes and three light-emitting diodes, so that an approximately hexagonal light body is created by means of the total of 19 light-emitting diodes. In particular with such a number of diodes it is possible to use different light-emitting diodes, i.e. light-emitting diodes that emit different colors of light, from which a corresponding mixed color of light can be created depending on the composition of the light-emitting diodes. Of course, it is also possible to control individual diodes or groups of diodes separately via a control circuit (not shown), which opens up further variation options, even in chronologically successive changes.

Fig. 6 shows an enlarged view of a unit formed from a reflector 15 and a light-emitting diode 13. The light-emitting diode 13 has wire-shaped power connections which are plugged into the aforementioned circuit board 14 as connectors.

in which corresponding power connections are provided. The inner casing of the reflector is conical in order to make it possible to use light emitted radially from the LED 13. The reflector has a central opening (bore) whose diameter is the same as the diameter of the LED glass body, so that the reflector simultaneously serves as a centering element for the LED and also for the longitudinal axial alignment of the LED. The reflector 15 can be inserted in a friction-locked manner into a housing 21 which has an external thread 22 in the lower area for screwing into a corresponding internal thread of a receptacle in the presentation plate 10. Alternatively, the reflector 15 and the housing 21 can also be manufactured as a single piece. Preferably, either the LED 13 is arranged alone or as an interchangeable LED/reflector unit in the presentation plate.

Claims (7)

1. Lamp, in particular a table lamp or presentation plate ( 19 ), with a lamp body accommodating the light source or the light sources, characterized in that the lamp body ( 11 ) has an upper horizontally arranged flat surface ( 17 ) from which the rays originating from at least one light source ( 13 ) emerge vertically. 2. Lamp according to claim 1, characterized in that the lamp body ( 10 ) is disc-shaped. 3. Lamp according to claim 1 or 2, characterized in that the light source or light sources are light-emitting diodes ( 13 ). 4. Lamp according to one of claims 1 to 3, characterized in that the or at least one of the light-emitting diodes ( 13 ) is replaceably plugged into a socket or on a circuit board. 5. Lamp according to one of claims 1 to 4, characterized in that the diode ( 13 ) or at least one of the diodes ( 13 ) is arranged in a hollow reflector ( 15 ). 6. Lamp according to claim 5, characterized in that a plurality of light-emitting diodes ( 13 ) are provided, each of which is surrounded by a hollow reflector, the hollow reflectors ( 15 ) preferably forming a honeycomb-shaped body. 7. Lamp according to one of claims 1 to 6, characterized in that the lamp body ( 10 ) consists at least partially of light-transparent plastic.